A robot includes: a first arm having a first body, a first housing fixed to the first body, and a first gear transmitting power to a rotary member supported by the first housing so as to be rotatable; a second arm supporting the first arm and having a second body, a second shaft having a second gear meshing with the first gear, and a second bearing supporting the second shaft so that the second shaft is rotatable relative to the second body; and a channel in the arms. An inlet of the channel is formed in an outer surface of the first body, an outlet of the channel opening into a space in which an outer peripheral surface of the second shaft and the second bearing are arranged inside the second arm, the channel extending from the inlet to the outlet through inside of the first body.

The present invention relates to a grease replacement method of replacing grease in a case (84) including a sealable gear chamber (31, 36) accommodating a gear (85) as a member to be lubricated, a grease injection port (61, 62) configured to inject grease into the gear chamber (31, 36), and a discharge port (32, 37) configured to discharge the grease in the gear chamber (31, 36), and a grease suction device to be used to perform this method. The grease replacement method includes a suction step (S2) of sucking the grease in the gear chamber (31, 36) from the grease injection port (61, 62) with the discharge port (32, 37) being open, and discharging the grease outside the case (84), and an injection step (S4) of injecting new grease into the grease injection port (61, 62) and supplying the new grease to the gear (85). This facilitates discharging of old grease.

A ring seal and a robot. The ring seal includes an outer circumferential wall and an annular portion. The outer circumferential wall extends in an axial direction of the ring seal. The annular portion extends from a side of the outer circumferential wall toward an interior of the outer circumferential wall in a radial direction of the ring seal. As viewed in a cross section taken along the radial direction, the annular portion and the outer circumferential wall form an L shape.

A lubricant container part 7 is provided to a robot arm drive unit 5 pertaining to a first arm 2, 2a and a second arm 3, 3a which displace relative to each other via a reduction mechanism 4, and a receiving member 9, 9a having a recess 10 forming a concave shape facing vertically upward is provided below the liquid level 8 of a lubricant 6 inside the lubricant container part 7, and through this configuration, even when time elapses after stopping of the robot, the lubricant can be extracted from the receiving member 9, 9a in a manner suitable for observing the state of iron powder included in the lubricant 6.

A parallel link robot includes a main body, a number of driving mechanisms provided in the main body, a number of link units each having one end connected to corresponding one of the plurality of driving mechanisms, a movable plate disposed beneath the main body, and supported by the other ends of the number of link units, and an oil tray placed adjacently to the lower surface of the main body, where the oil tray is detachably attached to the main body.

A robot arm includes a first structural component, in particular a main frame for fixing the robot arm in its surroundings, a second structural component, in particular a carousel, which is mounted rotatably about an axis of rotation on the first structural component and a transmission for twisting the second structural component relative to the first structural component. The transmission includes a transmission casing and, a casing of the first structural component has at least one integrated cavity for receiving lubricant for the transmission. The cavity is fluidically connected to the transmission casing by at least one connecting duct in the casing of the first structural component

A finger includes a pair of overhanging portions that project out laterally from a main body portion. Outer peripheral surfaces of the overhanging portions are made up from five surfaces including upper surfaces, side surfaces, lower surfaces, first end surfaces, and second end surfaces. Crowning is applied to the intersections between these surfaces.

A wrist structure of a robot capable of protecting an oil seal of a wrist structure from a high-pressure jet for cleaning or from external foreign matter or the like. A wrist structure of a robot includes a wrist body, a holder attached to the wrist body, a wrist flange rotatably supported by the holder, an oil storage provided between the wrist body and the holder, an oil seal disposed between the holder and the wrist flange and configured to prevent oil from leaking from the oil storage, and a cover that is formed integrally with the holder and that covers the oil seal from the outside between the holder and the wrist flange.

A linear robot according to the present disclosure includes a main body unit including a main body base part seated on a ground surface, and main body sidewall parts protruding in an upward direction by a predetermined thickness from two opposite sides of the main body base part, the main body unit having an internal space defined by the main body base part and the main body sidewall parts; a transfer block unit partially accommodated in the internal space of the main body unit, configured to linearly move in one direction, and having an upper portion on which a transfer target object is seated, the transfer block unit being configured to transfer the transfer target object from a first position to a second position; and a pair of guide rail units disposed between the main body unit and the transfer block unit, coupled to the main body unit, and configured to guide the transfer block unit, in which the main body sidewall parts each have a guide rail unit accommodation groove recessed by a predetermined length in a direction perpendicular to the upward direction, and at least a part of a surface of the guide rail unit accommodation groove has an uneven machined surface.

A robot including, a motor attached to one end surface of a casing of an arm, a reducer output shaft attached to the other end surface of the casing by bolts, a hole provided in the casing, and through which the output shaft of the motor is inserted, a first sealing member sealing a space between the hole and the output shaft, a second sealing member sealing a space between the other end surface and the end surface of the reducer output shaft, a recessed portion provided on a side of the other end surface of the casing and recessed in a direction along the central axial line of the reducer output shaft; and a lubricant agent supply hole provided in the casing and extending in a substantially radial direction or in a radial direction of the reducer output shaft, the lubricant agent supply hole communicating to the recessed portion.